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Abstract
Zeolitic imidazolate frameworks (ZIFs), such as ZIF-8, possess high surface area and tunable porosity, making them attractive for many applications. However, their structural flexibility can hinder performance in pressure-dependent processes like gas separation or water intrusion for energy storage. Several strategies have been proposed to control the characteristics of these materials but the general laws still remain elusive. In this study, we employ a combined theoretical/experimental approach to address this question. We focus on ZIF-8 and its derivatives to illustrate principles of endogenic and exogenic tuning with respect to processes related to intrusion of gasses and liquids in the porous system. Density functional theory and molecular dynamics simulations is used to investigate how linker swinging, the fundamental process controlling intrusion-extrusion/gas separation, depends on the endo-/exogenic modifications. These results will be tested against experimental pressure-volume-temperature liquid porosimetry data. Our results ultimately offer a design pathway for tailoring optimization of ZIF-based MOFs and, possibly, MOFs and porous materials at large.
Supplementary materials
Title
Supporting Information
Description
Synthesis and XRD pattern of ZIF-8 samples. Visual representation of the unit cells and the computational slabs; lattice parameter vs filling of the ZIF-8 slab; radial distribution function of all ZIF-8 rotated configurations; rotational energy wells of ZIF-8_X systems; PV-isotherms of ZIF-7-8; additional explanation of ZIF-8 metastable state; RMD framework.
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